A deep understanding of a chemical compound's properties is fundamental to its successful application in research and industry. NINGBO INNO PHARMCHEM CO.,LTD. focuses on providing clear and comprehensive information on key chemical intermediates, including 4,4'-[(4-Bromophenyl)imino]dibenzaldehyde, CAS 167859-41-8. This compound, also identified as 4,4'-[(4-bromophenyl)azanediyl]dibenzaldehyde, possesses a unique set of characteristics that make it valuable in sophisticated chemical processes.

The molecular structure of 4,4'-[(4-bromophenyl)imino]dibenzaldehyde, represented by the formula C20H14BrNO2, and its molecular weight of 380.24, provide the basis for its reactivity and application. The compound typically presents as a white to off-white powder, with a significant melting point of 217°C, indicating a stable crystalline structure. This stability is crucial for its use as a reliable intermediate in multi-step syntheses.

From a synthesis perspective, the formyl groups and the brominated phenyl ring offer multiple points for further chemical modification. This makes it an attractive starting material for researchers aiming to create novel organic molecules. The high purity, often 97% or more, ensures that synthetic outcomes are predictable and that the final products meet stringent quality requirements, particularly when used as organic intermediates for OLED materials.

When chemists search for N,N-bis(4-formylphenyl)-amine derivatives, they are often exploring pathways to create materials with specific electronic or optical properties. The bromo-substitution on the phenyl ring in 4,4'-[(4-bromophenyl)imino]dibenzaldehyde can be further utilized in cross-coupling reactions, such as Suzuki or Sonogashira couplings, to introduce more complex functionalities.

NINGBO INNO PHARMCHEM CO.,LTD. is committed to supporting scientific advancement by providing access to well-characterized chemical intermediates. Our supply of 4,4'-[(4-bromophenyl)imino]dibenzaldehyde is a testament to our dedication to empowering innovation in chemical synthesis and material science, enabling breakthroughs in fields ranging from pharmaceuticals to advanced electronics.